Semi-universality of CFTd entropy at large spin

Abstract

The thermal partition function, Z, of a CFTd on Sd-1 is parameterized by the inverse temperature β along with d/2 angular velocities ωi. In this paper, we investigate the behaviour of this partition function when n of the ωi are scaled to unity (the largest allowed value) at fixed values of the other ( d/2-n) angular velocities. We argue that Z develops a simple pole in (1-ωi) for each ωi that is scaled to unity. The residue of this product of poles is a theory dependent (so non-universal) function of β and the fixed angular velocities. The inverse Laplace transformation of this partition function constrains the functional form of the field theory entropy as a function of charges in a limit in which angular momenta and the twist are scaled as follows. While n special angular momenta J1… Jn are scaled to infinity, the twist and the other angular momenta - collectively denoted xi - are also taken to infinity but at the slower rate that ensures that the scaled charges xi/(J1 J2 … Jn)1n+1 are held fixed. In this limit, we demonstrate that the scaled entropy S/(J1 J2 … Jn)1n+1 depends only on the d/2-n+1 scaled charges defined above (the precise form of this dependence is non-universal). We verify our predictions (and compute all non-universal functions) in the case of free scalar theories (which show surprisingly rich behaviour) as well as large N, strongly coupled N=4 Yang Mills theory. The last theory is analyzed in the bulk via the AdS/CFT correspondence. In the scaling limit described above, its phase diagram displays sharp phase transitions between black hole, grey galaxy, and thermal gas phases.